Topography measurements of high NA aspherical microlenses by digital holographic microscopy with spherical illumination

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TitreTopography measurements of high NA aspherical microlenses by digital holographic microscopy with spherical illumination
Type de publicationConference Paper
Year of Publication2017
AuteursJozwik M, Mikula M, Kozacki T, Kostencka J, Gorecki C
EditorLehmann P, Osten W, Goncalves AA
Conference NameOPTICAL MEASUREMENT SYSTEMS FOR INDUSTRIAL INSPECTION X
PublisherSPIE
Conference Location1000 20TH ST, PO BOX 10, BELLINGHAM, WA 98227-0010 USA
ISBN Number978-1-5106-1104-7; 978-1-5106-1103-0
Mots-clésaspheric surface, digital holographic microscopy, microlens, spherical wave illumination, topography measurement
Résumé

In this contribution, we propose a method of digital holographic microscopy (DHM) that enables measurement of high numerical aperture spherical and aspherical microstructures of both concave and convex shapes. The proposed method utilizes reflection of the spherical illumination beam from the object surface and the interference with a spherical reference beam of the similar curvature. In this case, the NA of DHM is fully utilized for illumination and imaging of the reflected object beam. Thus, the system allows capturing the phase coming from larger areas of the quasi-spherical object and, therefore, offers possibility of high accuracy characterization of its surface even in the areas of high inclination. The proposed measurement procedure allows determining all parameters required for the accurate shape recovery: the location of the object focus point and the positions of the illumination and reference point sources. The utility of the method is demonstrated with characterization of surface of high NA focusing objects. The accuracy is firstly verified by characterization of a known reference sphere with low error of sphericity. Then, the method is applied for shape measurement of spherical and aspheric microlenses. The results provide a full-field reconstruction of high NA topography with resolution in the nanometer range. The surface sphericity is evaluated by the deviation from the best fitted sphere or asphere, and the important parameters of the measured microlens: e.g.: radius of curvature and conic constant.

DOI10.1117/12.2270150